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Learning Coupled Earth System Dynamics with GraphDOP

graph-neural-networks › graph-learning

📄 Abstract

Abstract: Interactions between different components of the Earth System (e.g. ocean, atmosphere, land and cryosphere) are a crucial driver of global weather patterns. Modern Numerical Weather Prediction (NWP) systems typically run separate models of the different components, explicitly coupled across their interfaces to additionally model exchanges between the different components. Accurately representing these coupled interactions remains a major scientific and technical challenge of weather forecasting. GraphDOP is a graph-based machine learning model that learns to forecast weather directly from raw satellite and in-situ observations, without reliance on reanalysis products or traditional physics-based NWP models. GraphDOP simultaneously embeds information from diverse observation sources spanning the full Earth system into a shared latent space. This enables predictions that implicitly capture cross-domain interactions in a single model without the need for any explicit coupling. Here we present a selection of case studies which illustrate the capability of GraphDOP to forecast events where coupled processes play a particularly key role. These include rapid sea-ice freezing in the Arctic, mixing-induced ocean surface cooling during Hurricane Ian and the severe European heat wave of 2022. The results suggest that learning directly from Earth System observations can successfully characterise and propagate cross-component interactions, offering a promising path towards physically consistent end-to-end data-driven Earth System prediction with a single model.

Authors (10)

Eulalie Boucher

Mihai Alexe

Peter Lean

Ewan Pinnington

Simon Lang

Patrick Laloyaux

+4 more

Submitted

October 23, 2025

arXiv Category

physics.ao-ph

arXiv PDF

Key Contributions

GraphDOP is a novel graph-based machine learning model that forecasts weather directly from raw observations, learning coupled Earth system dynamics without relying on traditional physics-based NWP models or explicit coupling. It embeds diverse observation sources into a shared latent space, implicitly capturing cross-domain interactions.

Business Value

Improved weather forecasting accuracy and lead time can benefit numerous industries, including agriculture, transportation, energy, and disaster management, leading to significant economic and societal impact.

Paper Metadata

Innovation Type

Algorithmic Innovation

Deployment Feasibility

Requires access to vast amounts of real-time satellite and in-situ observational data. Computational resources for training and running GNNs on global Earth system data are substantial.

Limitations Addressed

Addresses the challenge of accurately representing coupled interactions between different components of the Earth System in traditional NWP systems, and the reliance on reanalysis products or complex physics-based models.

Performance Gains

Enables predictions that implicitly capture cross-domain interactions in a single model, potentially improving forecast accuracy and efficiency.

Technical Tags

graph neural networksearth system modelingweather forecastingnumerical weather prediction (NWP)satellite datain-situ observationsmulti-domain interactionslatent space embeddingspatio-temporal prediction

Research Topics

Earth System ScienceMeteorologyMachine LearningGraph Neural NetworksData Assimilation

Methods & Architectures

Graph-based machine learningGraphDOP modelLatent space embeddingEnd-to-end learningMulti-modal data fusion Graph Neural Networks (GNNs)

Applications & Tasks

Meteorology Climate Science Earth System Science Environmental Monitoring ForecastingSpatio-temporal PredictionModeling Complex Interactions Weather ForecastingPredicting Earth System DynamicsModeling coupled interactions between Earth components (ocean, atmosphere, land, cryosphere)

Datasets & Benchmarks

Datasets

satellite observations, in-situ observations

Related Fields

MeteorologyClimate ScienceGeophysicsMachine LearningData Science

Keywords

Graph Neural NetworksEarth Systemweather forecastingNWPsatellite dataobservationsclimate modelingmachine learningspatio-temporallatent spaceGraphDOP

Academic Context

#Earth System Science#Meteorology#Machine Learning#Graph Neural Networks#Data Assimilation

Technology Stack

Frameworks & Libraries

Graph Neural Networks (GNNs)

Commercial Potential

Potential Products

Advanced weather forecasting systemsClimate simulation tools

Target Industries

MeteorologyAgricultureEnergyTransportationInsuranceDisaster Management

Use Case Examples

Predicting extreme weather eventsImproving seasonal climate forecastsModeling the impact of climate change on Earth systems

Competitive Edge

Presents a novel data-driven approach using GNNs that bypasses traditional physics-based NWP models, offering a potentially more efficient and integrated way to model complex Earth system dynamics.

Market Opportunity

The global weather forecasting market is substantial and critical for many sectors.

Revenue Models

Licensing of the forecasting model or providing forecasting services.

Resource Requirements

Compute Needs

Very high, for training GNNs on global Earth system data.

Data Requirements

Requires access to diverse, large-scale Earth observation data (satellite, in-situ).

Deployment Constraints

Need for robust data pipelines, significant computational infrastructure, and validation against established NWP models.

Scalability

Scalability depends on the GNN architecture and the efficiency of distributed training frameworks.

Production Readiness

Maturity Level

Research

Time to Market

Long, requires extensive validation and integration into operational forecasting systems.

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